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Received 17 October 1997; accepted after revision 3 December 1997.
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ABSTRACT |
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INTRODUCTION |
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In this study, we have used simultaneous paired recordings and investigated the effects of changing temperature on the reliability and variability of local synaptic transmission between pyramidal cells in layer 2/3 of the visual cortex of the rat at low frequencies of action potential firing.
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METHODS |
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Sprague-Dawley rats (20-22 days old) were killed by cervical dislocation and slices (400 µm thick) of visual cortex were prepared by conventional methods (Larkman et al. 1997). The slices were maintained in artificial cerebrospinal fluid (ACSF) containing (mM): 119 NaCl, 3·5 KCl, 1 NaH2PO4, 2·5 CaCl2, 1 MgSO4, 26 NaHCO3 and 10 glucose. The ACSF reservoir was bubbled with 95 % O2 and 5 % CO2 at room temperature (21-25°C) throughout. Closely adjacent pairs of pyramidal neurones were selected by infrared differential interference contrast video microscopy (Dodt & Zieglgänsberger, 1990) using an upright microscope, and whole-cell voltage recordings were obtained from their cell bodies using the ruptured patch technique. Recording pipettes contained (mM): 110 potassium gluconate, 10 KCl, 2 MgCl2, 2 Na2ATP, 10 EGTA and 10 Hepes, adjusted to pH 7·3 and 270 mosmol. On-line spike-triggered averaging was used to detect EPSPs produced in one cell by action potentials induced in the other. We always inspected individual traces and averaged at least fifty trials to maximize the chance of identifying even weak and unreliable connections. Once a connection had been identified, single presynaptic spikes were usually induced by 100 ms pulses repeated at 0·5 Hz. Individual records were low-pass filtered (usually at 2 kHz), digitized (usually at 5 kHz) and stored on disk for analysis off-line.
The temperature of the preparation was monitored by a small thermocouple probe placed in the recording chamber close to the slice, and altered by heating or cooling the incoming ACSF using a water jacket around the inlet tube. We waited until a stable temperature within ± 1°C of the target temperature had been achieved and typically a hundred or more trials were recorded at each temperature. The usual temperature sequence was 23, 30, 36, 18 and 13°C, although in some cases not all temperatures could be tested before some recording instability occurred. We did not monitor the pH of the ACSF during recording, but in control experiments we found that if the ACSF was gassed at room temperature, no changes in pH occurred on heating or cooling over the range 13-36°C within the time period (less than 2 min) that the ACSF was in contact with the slices. Resting membrane potentials were -67 ± 7 mV at room temperature and were held approximately constant during the temperature changes, using injected current if necessary. Most neurones showed a tendency to depolarize during cooling.
EPSP amplitudes and shape indices were analysed using a computer optimizing routine that fitted the sum of two exponential functions to each record. The onset of the EPSP and the time interval over which the fitting was to be performed were determined by eye. The fit interval was chosen to include the rising phase and as much of the falling phase of the EPSP as possible before contamination by noise or spontaneous synaptic events became apparent. The EPSP latency was measured from the peak of the presynaptic action potential to the onset of the EPSP. The EPSP peak amplitude, 10-90 % rise time, width at half-amplitude and time integral were measured from the fitted line. Apparent failures of transmission were identified by eye. The level of the contaminating recording noise is difficult to quantify by this method, but our calibration using injected current pulses suggests that it is low compared with conventional methods involving the comparison of average voltages within brief time windows. Estimates of EPSP variability have therefore not been corrected for noise, and the amplitudes of failures have been taken to be zero.
The locus of the change in synaptic strength was investigated using graphs of the (coefficient of variation)-2 of the EPSP against its mean. It has been suggested that, for a range of statistical models of transmitter release, including Poisson and binomial quantal models (Malinow & Tsien, 1990), the trajectory of such graphs will be close to or steeper than the diagonal if the change is due to an altered number of quanta released per trial. However, if the change is due to an alteration in the size of the effect produced by each quantum, the trajectory will be close to horizontal. There are situations in which these plots can be misleading, but when applied to paired recordings, when it is known that a single presynaptic axon is stimulated reliably, their interpretation is much more straightforward and unequivocal (Faber & Korn, 1991).
Spontaneous miniature EPSPs (mEPSPs) were recorded from a sample of ten pyramidal neurones in the presence of 1 µM tetrodotoxin (TTX) and 100 µM picrotoxin. One hundred sweeps of data, each 400 ms in length, were recorded to disk and analysed off-line. The mEPSPs were identified by eye on the basis of their rapid rise and slow decay phases and their amplitudes were measured using the same fitting procedure as for evoked EPSPs. Samples of 125 mEPSPs were analysed at each temperature for each neurone.
Measurements of changes in neuronal input resistance and membrane time constant with temperature were obtained from the averaged responses to brief pulses (1 ms) of hyperpolarizing current injected into a further sample of six pyramidal neurones.
Values quoted in the text are given as means ± standard deviation; the error bars in the figures show standard error of the mean.
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RESULTS |
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The proportion of connected neuronal pairs (Fig. 1A) was quite high (approximately one in every seven pairs tested) and a total of twelve connections was investigated. The connections varied widely in their strength, with EPSP mean peak amplitudes ranging from approximately 40 µV to 2 mV at 23°C. Failures of transmission could be distinguished with reasonable certainty (Fig. 1B), and the proportion of apparent failures was also highly variable (ranging between 0 and 0·81 at 23°C). Large EPSPs showed fewer failures than small ones (Fig. 1C), suggesting that the mean number of quanta of transmitter released per action potential (m) was an important factor in determining the average size of the EPSP produced at a given connection.
We investigated the properties of the EPSP over a range of temperatures between 13 and 36°C. In every case, the EPSP mean peak amplitude increased with temperature. When the EPSP amplitudes were normalized to their amplitude at 23°C and pooled, there was a roughly linear increase in amplitude with temperature (Fig. 1D), but individual connections differed in their behaviour. The weaker connections showed dramatic increases right across the temperature range tested. The stronger connections showed less increase, especially over the higher temperature range, with some actually showing a decrease between 30 and 36°C. The proportional increase in amplitude between 23 and 36°C was inversely related to the amplitude at 23°C (r = 0·737, P < 0·01; data not shown). The group mean peak amplitude at 36°C was 618 ± 497 µV, very much in line with an earlier microelectrode study of similar connections at a similar temperature (550 ± 490 µV; Mason, Nicoll & Stratford, 1991).
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Figure 1. General properties of synaptic connections A, paired recording showing presynaptic action potentials (upper trace) and averaged postsynaptic responses (lower trace; averages of 50 trials); those shown by the thick lines were recorded at 23 °C, thin lines at 36 °C and dotted lines at 13 °C. B, examples of superimposed consecutive single trials from EPSPs of different mean amplitudes, recorded at 23 °C: upper traces, strong connection showing no failures; middle traces, connection of moderate strength, showing one failure; lower traces, weak connection. Note that the failure can be distinguished from the successes, even though the peak amplitude of the smaller success is only approximately 170 µV. C, graph showing the proportion of transmission successes as a function of the EPSP mean peak amplitude, recorded at 23 °C and showing that large EPSPs failed less often than small ones. Each point represents an individual connection and values were calculated for epochs of 100 trials. D, graph showing how the mean EPSP amplitude for the twelve connections tested increased with temperature. Because the EPSPs differed greatly in size, the mean amplitudes for each were normalized to their mean amplitude at 23 °C before pooling. Means were calculated for epochs of 50 or 100 trials. The continous line was fitted by linear regression (r = 0·996). | ||
In every case the reliability of transmission improved with increasing temperature (Fig. 2A). The group mean failure rate decreased from 0·56 ± 0·32 at 13°C to 0·16 ± 0·18 at 36°C (Fig. 2B). In five of the twelve connections the proportion of failures was 1 % or less at 36°C. As the reliability of transmission increased with temperature, so the trial-to-trial variability decreased, from a mean coefficient of variation (CV) of 2·33 ± 2·01 at 13°C to 0·61 ± 0·37 at 36°C (Fig. 2C).
) increased dramatically, but the mean potency of the connections (the mean amplitude of the successes; 
) did not increase. The mean success rate at 36 °C was 0·64, implying a mean release probability of 0·64 for these connections at this temperature. D, examples of five consecutive trials from a strong, putative multi-site connection. At 23 °C this connection showed failures, latency jitter and substantial amplitude fluctuations (upper traces). At 36 °C, however (lower traces), it did not fail and showed little more amplitude variability than expected from the background noise. E, graph showing the fall in CV with temperature for the connection shown in D, calculated for epochs of 50 trials. At 36 °C, the CV was only 0·06, consistent with a release probability close to 1 at this temperature.
and 16·2 ± 5·9 ms, respectively, at 36°C, to 613 ± 400 M
